There are provided systems and methods for a physical stand for multiple device orientations and peripheral card reader. A device stand may include a dock that allows for placement and securing of a computing device within the device case, such as through a locking or connecting mechanism. The device dock further includes a peripheral component, such as a physical card reader, that allows for reading and entry of card data into the computing device for use with an electronic transaction processing application on the computing device. This allows the computing device to process transactions electronic with an online service provider. Further, the device stand includes a hinge or joint that allows for rotating and inverting of the computing device over a curved extension from a base of the device stand, which allows the computing device to be viewed in multiple directions and orientations.

A tag reading apparatus comprises a passage that is configured to receive an RFID-tagged article that is to be registered in a transaction. The passage has an inlet end and an outlet end separated from each other in a first direction and width in a second direction. An antenna is in the passage at a position between the inlet and outlet ends in the first direction. An RFID reader is provided to read an RFID tag according to a response wave from the RFID tag received via the antenna. A controller is configured to identify the RFID-tagged article as being in the transaction according to a change in the response wave (such as a phase difference or intensity) corresponding to a movement of the RFID-tagged article from the inlet end to the outlet end.

Aspects described herein may allow for detecting fraudulent transaction requests using light sensors on smartcards. A computing device may receive, from a terminal, a request to approve a transaction. The request may comprise a timestamp corresponding to a time when the transaction was requested, a transaction type associated with the transaction, and an identification of a card associated with the transaction. The computing device may also receive, from one or more light sensors associated with the card, light data. The light data indicates an amount of ambient light during a time period when the transaction was requested. The computing device may determine, based on the transaction type, a model of expected ambient light. If the light data corresponds to the model, the computing device may send, based on the determination that the light data corresponds to the model, an approval of the request.

In some implementations, a point of sale (POS) system may store a card read failure indication based on detecting that a transaction terminal failed to read information associated with a transaction card, wherein the card read failure indication includes information that indicates whether the transaction terminal failed to read the information associated with the transaction card from a chip, a magnetic stripe, or a contactless device. The POS system may transmit information associated with the card read failure indication to an external device based on detecting a successful transaction subsequent to the transaction terminal failing to read the information associated with the transaction card, wherein the information associated with the card read failure indication is transmitted to enable the external device to determine whether one or more of the transaction card or the transaction terminal is defective.

A cash-dispensing machine (e.g., a casino kiosk or bank ATM) enables a user to use a bank card (e.g., a credit or debit card) to purchase a negotiable instrument via a quasi-cash transaction, redeem the negotiable instrument, and dispense paper currency for the redeemed negotiable instrument without having to go elsewhere (e.g., a casino cage) to redeem the negotiable instrument. The machine enables a user-verification process to be performed to verify the identity of the user before allowing the negotiable instrument to be redeemed.

The present invention provides a method and system for verifying and tracking identification information. In an embodiment of the invention, a system for delivering security solutions is provided that includes at least one of the following: a radio frequency (RF) identification device, an identification mechanism (e.g., a card, sticker), and an RF reader.

The present application discloses a wearable apparatus having an apparatus main body including at least one receptacle for detachably attaching a smartcard. The wearable apparatus is compatible with a plurality of smartcards.

A portable scanner with improved user feedback provides scan data to a networked computing node via a wireless interface and the Internet. The portable scanner receives user feedback information from the networked computing node via the wireless interface and the Internet. The user feedback information indicates successful entry of the scan data into a database, or alternatively successful receipt of the scan data by the networked computing node. The portable scanner sets a scan status indicator to a final state in response to the user feedback information. Optionally, the database is a remote database that a local database is synchronized with, and/or the database is associated with the networked computing node. Optionally the portable scanner is wearable. Optionally the portable scanner is compatible with barcode and/or RFID technologies.

A card reader includes a card conveyance path comprising upper and a lower conveyance paths to convey a card inserted into a device; and a reading unit that reads information on the card. Lower concave and convex portions are provided on an upper surface of the lower conveyance path behind the reading unit. Upper concave and convex portions are provided on a lower surface of the upper conveyance path to be fitted to the lower concave and convex portion. A pressing unit provides a fitted state of the lower and upper concave and convex portions when no object is present. A detection sensor detects a state where an interval between the lower and upper concave and convex portions is widened. The detection sensor detects the state where the interval is widened, to recognize that an object is inserted between the lower and upper concave and convex portions.

Various embodiments described herein provide multi-projector (i.e., two or more) imaging apparatuses utilizing integrated illumination-aimer optics. Embodiments of the present disclosure minimize irreparable component offset to improve overall accuracy associated with the functioning of the apparatuses. Additionally, the integrated illumination-aimer optics enables embodiments disclosed herein to be provided in a significantly smaller form factor than conventional multi-projector imaging apparatuses. An example apparatus includes a near-field imaging lens and a far-field imaging lens, an integrated illumination-aimer optics positioned between the near-field imaging lens and the far-field imaging lens, a near-field illuminator source and a far-field illuminator source positioned for projecting via the integrated illumination-aimer optics, a near-field imaging sensor associated with the near-field imaging lens, a far-field imaging sensor associated with the far-field imaging lens, and an apparatus chassis to align the various components for operation.